IMU Micro SENSOR
IMU basato su MEMS
Compatto e a bassa potenza, ideale per UAV, veicoli autonomi ed elettronica portatile.
IMU basato su FOG
Prestazioni ad alta precisione, senza deriva, perfette per la navigazione inerziale e i sistemi marini.
IMU basato su RLG
Ultra-accurato, progettato per la guida missilistica e le applicazioni aerospaziali.
Micro High-Tech Company presents a complete line of MEMS-based Gyroscope, Accelerometer,
IMU, North Seeker, INS+GNSS with different precision levels.
MEMS based inertial sensors have great performances
Sistemi di navigazione inerziale (INS) basati su MEMS offrono una navigazione accurata e affidabile per applicazioni in robotica, automotive e aerospaziale.
INS basati su MEMS
AG - SENSOR series
7 prodotti
ACM Sensor
12 prodotti
C - Series Micro Sensor
1 prodotti
Prodotti
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Il modulo di misura inerziale U2650 MEMS è un modulo di misura inerziale MEMS a 9 assi altamente affidabile ed economico, ampiamente applicabile a campi come robot umanoidi, robot subacquei e AGV. La serie U2650 di moduli di misura inerziali integra giroscopi MEMS ad alte prestazioni, accelerometri MEMS e sensori magnetici all'interno di un'unica struttura e incorpora algoritmi di atteggiamento per fornire un'uscita in tempo reale di velocità angolare, accelerazione e informazioni sull'atteggiamento del prodotto.
1 Encapsulation information 2
1.1 High performance accelerometer, packaged in a 48-pin ceramic package 2
1.2 Accelerometer axial direction 3
1.3 PIN definition description 3
1.4 PIN description 4
2 Reference circuit 5
2.1 Schematic design 5
2.2 PCB design 6
2.2.1 PCB layout and routing 6
2.2.2 PCB package 7
2.2.3 Development board 7
2.2.4 Suggestion on board separation after welding 8
2.2.5 External reset pin device selection 8
3 Communication and Control 9
3.1 Hardware interface 9
3.1.1 SPI timing 9
3.1.2 SPI read-write control 10
3.2 Register description 11
3.2.1 Introduction to Register Format 11
3.2.2 Register content description 12
4 Sensor data format 14
4.1 Temperature data output 14
4.2 Acceleration data output 15
4.3 Data reading 16
4.4 Sensor data update 17
5 Reference suggestion 18
5.1 Welding suggestion 18
5.2 ESD protection advice 19
5.3 Installation reference 19
1 Encapsulation information 2
1.1 Ultra-high precision accelerometer, packaged in a 48-pin ceramic package 2
1.2 Accelerometer axis 3
2 Reference circuit 3
2.1.1 Schematic design 3
2.1.2 Pin definition description 4
2.1.3 Pin description 5
2.2 PCB design 6
2.2.1 PCB layout and routing 6
2.2.2 PCB package 7
2.2.3 Development board 8
2.2.4 Suggestion 11 on board separation after welding 9
2.2.5 External reset pin device selection 9
3 Communication and Control 10
3.1 Hardware interface 10
3.1.1 SPI timing 10
3.1.2 SPI read-write control 11
3.2 Register description 12
3.2.1 Introduction to Register Format 12
3.2.2 Register content description 13
4 Sensor data format 14
4.1 Temperature data output 14
4.2 Acceleration data output 15
4.3 Register read CRC check 16
4.4 Data reading 17
4.5 Sensor data update 18
5 Reference suggestion 19
5.1 Welding suggestion 19
5.2 ESD protection advice 21
5.3 Installation reference
Notes:
- Long-term repeatability: Accelerometers with a range of 32 ± 50g have undergone long-term repeatability testing, and test data spanning 1.5 years is available. The proportion of accelerometers with zero-bias repeatability < 0.2mg is 31%, the proportion with zero-bias repeatability < 0.5mg is 75%, the proportion with zero-bias repeatability < 1.2mg is 100%, the proportion of accelerometers with scale factor repeatability < 100ppm is 93.7%, and the proportion with scale factor repeatability < 200ppm is 100%.
- The smaller the measurement range, the higher the accuracy. For example, products with a ±2g measurement range have the best zero-bias stability indicator of 3μg, and also exhibit better long-term repeatability.
1. Product characteristics (FULL TECHNICAL DATA SHEET ON REQUEST)
C9-A is a high-precision 3D electronic compass with CAN protocol interface launched by Micro-Magic Inc, which introduces advanced 3D compensation patent technology from the United States, allowing accurate heading data to be provided even at a product tilt angle of ± 40 °.
The product has a small size, low power consumption, and can be applied in many fields such as antenna stability, vehicles, and system integration. Its high seismic resistance and reliability also enable the compass to work normally in extremely harsh environments, making it more suitable for today's miniaturized high-precision measurement and integrated control systems.
- Product characteristics FULL TECHNICAL DATA SHEET IN REQUEST
The G801-B series angle sensor adopts MEMS technology and magnetoelectric induction technology. It uses differential array magnetic sensitive elements and non-contact measurement of the rotating shaft. It senses the parallel magnetic field intensity of the permanent magnet installed at one end of the rotating shaft and performs linearity correction through MCU processing, temperature compensation, output signal standardized digital filtering, zero point setting, programmable intelligent control of multiple different slope settings, to achieve the absolute angular position of the output sensor within the range of 0 ~ 360°. Accuracy 0.2°, output RS232, RS485, CAN, 0-5V, 0.5-4.5V, 0-10V, 4-20mA, 0-20mA optional.
- Product characteristics
G802 series magnetic angle sensor uses MEMS technology to integrate the nanomagnetic beam thin film material and the differential array magnetic sensitive element to non-contact sense changes in the magnetic field. The system integrates (microcomputer) with the current transmitter and various protection circuits. Through DSP processing, it realizes simple intelligent control of linearity correction, temperature compensation, standardization of output signals according to the range, digital filtering, zero point setting, and multi-stage different slope settings. Realize the measurement of absolute position output at user set angles within the range of 0-360 °
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Product characteristics (FULL TECHNICAL DATASHEET ON REQUEST)
G803 low-cost series magnetic angle sensor uses MEMS technology to integrate the nanomagnetic focusing film material and the differential array magnetic sensitive element to non-contact sense changes in the rotating magnetic field.
The system integrates a microprocessor (micro-computer), a current transmitter and a variety of protection circuits. Through DSP processing, it can perform linearity correction, temperature compensation, standardization of output signals according to the range, digital filtering, zero point setting, and multi-segment different slope settings. Programmed intelligent control enables measurement of absolute position output at user-set angles within the range of 0 to 360°.
- Product characteristics
G810 series angle sensor combines an embedded microprocessor with a CNC anc-second level calibration device, programmed calibration and conversion, 0.1° high-precision measurement, multiple outputs RS232, TTL, RS485, RS422, CAN, 0-5V, 0.5-4.5V, 0-10V, 4-20mA, 0-20mA optional.
The magnetic angle sensor uses MEMS technology to integrate the nanomagnetic focusing thin film material and the differential array magnetic sensitive element to non-contact sense changes in the rotating magnetic field.
The system integrates micro-computer, voltage and current transmitters and various protection circuits. Through DSP processing, programmable intelligent control can be achieved for linearity correction, temperature compensation, standardization of output signals based on range, digital filtering, zero point setting, and multiple different slope settings.
- Product characteristics
The G820 series high-precision angle sensor is integrated with MEMS technology, low power consumption; By using magneto electric induction technology, precision bearings, differential array magnetic sensing elements, and non-contact measurement of the shaft, the parallel magnetic field strength of a permanent magnet installed at one end of the shaft is sensed and processed by MCU to achieve programmable intelligent control of linearity correction, temperature compensation, N-order digital filtering algorithm, zero point setting, and multiple different slope settings. The absolute angular position of the output sensor is achieved within the range of 0-360 °. Accuracy of 0.05 °, output RS232, TTL, RS485, CAN, 0-5V, 0.5, 4.5V, 0-10V, 4-20mA, 0-20mA optional.
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